Mapping of a Myosin-binding Domain and a Regulatory Phosphorylation Site in M-Protein, a Structural Protein of the Sarcomeric M Band

The myofibrils of cross-striated muscle fibers contain in their M bands cytoskeletal proteins whose main function seems to be the stabilization of the three-dimensional arrangement of thick filaments. We identified two immunoglobin domains (Mp2–Mp3) of M-protein as a site binding to the central region of light meromyosin. This binding is regulated in vitro by phosphorylation of a single serine residue (Ser76) in the immediately adjacent amino-terminal domain Mp1. M-protein phosphorylation by cAMP-dependent kinase A inhibits binding to myosin LMM. Transient transfection studies of cultured cells revealed that the myosin-binding site seems involved in the targeting of M-protein to its location in the myofibril. Using the same method, a second myofibril-binding site was uncovered in domains Mp9–Mp13. These results support the view that specific phosphorylation events could be also important for the control of sarcomeric M band formation and remodeling

Basic fibroblast growth factor has a differential effect on MyoD conversion of cultured aortic smooth muscle cells from newborn and adult rats

MyoD is a master regulatory gene for myogenesis that also converts many mesoderm-derived cells into the skeletal muscle phenotype. Rat aortic smooth muscle cells do not contain MyoD homologous mRNA. However, expression of an exogenously supplied MyoD gene in aortic smooth muscle cells cultured from newborn and adult animals converts these cells to elongated myoblasts and myotubes expressing the skeletal muscle genes for titin, nebulin, myosin, and skeletal α-actin. The presence of basic fibroblast growth factor during growth and serum starvation completely inhibits MyoD-mediated conversion in cultures of newborn smooth muscle cells. However, in smooth muscle cell cultures derived from adult rats the presence of fibroblast growth factor increases the conversion frequency. The differential response of exogenous MyoD suggests that the two morphological types of aortic smooth muscle cells, one typical for the newborn rat, the other for the adult rat, represent two distinctive states of differentiation

Basic fibroblast growth factor has a differential effect on MyoD conversion of cultured aortic smooth muscle cells from newborn and adult rats

MyoD is a master regulatory gene for myogenesis that also converts many mesoderm-derived cells into the skeletal muscle phenotype. Rat aortic smooth muscle cells do not contain MyoD homologous mRNA. However, expression of an exogenously supplied MyoD gene in aortic smooth muscle cells cultured from newborn and adult animals converts these cells to elongated myoblasts and myotubes expressing the skeletal muscle genes for titin, nebulin, myosin, and skeletal α-actin. The presence of basic fibroblast growth factor during growth and serum starvation completely inhibits MyoD-mediated conversion in cultures of newborn smooth muscle cells. However, in smooth muscle cell cultures derived from adult rats the presence of fibroblast growth factor increases the conversion frequency. The differential response of exogenous MyoD suggests that the two morphological types of aortic smooth muscle cells, one typical for the newborn rat, the other for the adult rat, represent two distinctive states of differentiation.</p

Cellular Mechanotransduction Relies on Tension-Induced and Chaperone-Assisted Autophagy

SummaryMechanical tension is an ever-present physiological stimulus essential for the development and homeostasis of locomotory, cardiovascular, respiratory, and urogenital systems [1, 2]. Tension sensing contributes to stem cell differentiation, immune cell recruitment, and tumorigenesis [3, 4]. Yet, how mechanical signals are transduced inside cells remains poorly understood. Here, we identify chaperone-assisted selective autophagy (CASA) as a tension-induced autophagy pathway essential for mechanotransduction in muscle and immune cells. The CASA complex, comprised of the molecular chaperones Hsc70 and HspB8 and the cochaperone BAG3, senses the mechanical unfolding of the actin-crosslinking protein filamin. Together with the chaperone-associated ubiquitin ligase CHIP, the complex initiates the ubiquitin-dependent autophagic sorting of damaged filamin to lysosomes for degradation. Autophagosome formation during CASA depends on an interaction of BAG3 with synaptopodin-2 (SYNPO2). This interaction is mediated by the BAG3 WW domain and facilitates cooperation with an autophagosome membrane fusion complex. BAG3 also utilizes its WW domain to engage in YAP/TAZ signaling. Via this pathway, BAG3 stimulates filamin transcription to maintain actin anchoring and crosslinking under mechanical tension. By integrating tension sensing, autophagosome formation, and transcription regulation during mechanotransduction, the CASA machinery ensures tissue homeostasis and regulates fundamental cellular processes such as adhesion, migration, and proliferation